SU875562A1 - Dc voltage-to-ac staircase voltage converter - Google Patents

Description

(54) CONSTANT VOLTAGE CONVERTER TO VARIABLE STACKED

Claims (3)

The invention relates to a converter technique and can be used as a power source for various loads of the type of an alternating current electric motor, and also as a link of the alternating current in converters with an intermediate frequency increase. DC-to-AC converters are known that form step voltage on the load, see for example i. j and 2 J. The closest in technical essence is a converter containing h of the same type inverters,. feeding from one source of constant voltage. The output windings of the transformers of all inverters are connected in series and a load 3 is connected to them. However, control pulses to each subsequent inverter are applied with a certain phase shift relative to control pulses of a pre-inverter inverter. As a result, the output voltage of the converter has a step form, in a particular case, approaching a sinusoidal. To obtain the phase shift of the control pulses, various annular frequency dividers of the master oscillator pulses are used. Moreover, the smaller the required phase shift of the control pulses by one inverter relative to the other, the greater the division factor the frequency divider must have, which makes the inverter control system more complex and its reliability to decrease. Since frequency dividers are usually performed on integrated circuits, in order to control the power thyristors: the received pulses must be amplified in power and galvanically released from the control system. Dp this goal in the control system is introduced power amplifier. usually with transformer output. A separate power supply is required to power the control system. The purpose of the invention is to simplify the control system of the converter and increase its reliability. The goal is achieved by the fact that, in a known converter, a constant-to-variable step voltage contains Q single-phase thyristor inverters loaded on transformers, the output windings of which are connected in series and form the common output of the inverter and the master oscillator controlling the operation of the first inverter in parallel to one A circuit is connected from the thyritors of each inverter; it consists of successively connected delay lines, a capacitor, and a primary winding the matora, the secondary windings of which through the resistors are connected to the control transitions of the corresponding inverter thyristors K-f-1. In addition, the delay lines are controllable. In this case, the delay lines are made in the form of throttles; FIG. 1 shows a jet circuit of a converter containing inverters; FIG. 2 shows a scheme for receiving control pulses and transmitting them from one inverter to another. The converter contains five thyristor inverters 1-5, which are connected in power in parallel, and in output - sequentially due to the serial connection of the secondary windings of inverter transformers 6-10. Inverter 1 is supplied with control pulses from master oscillator P. An inverter, for example 1 (FIG. 4 d, four thyristors 12–15 contains four thyristors and a switching node 16. Parallel to one of the thyristors, for example, 14, a chain is turned on, sequentially connecting delay lines 17, capacitor 18 and primary winding 19 of a pulse transformer 20. Transformer 20 has four secondary windings 21-24, in series with which resistors 2528 are connected.Winding 21 through a resistor 25 is connected to the control transition of the inverter 2 thyristor 29. The winding 22 through the resistor 26 is connected to the control transition of the thyristor 30, the winding 23 through the resistor 27 is connected to the control to the transition of the thyristor 31, and the winding 24 through the resistor 28 is connected to the control transition of the thyristor 32. Inverter 2, except for the thyristors 29-32 It also contains a switching node 33. Similarly, the inverters 2 and 3, 3 and 4, as well as 4 and 5 are connected in a similar way. In the initial position, the thyristors of all the inverters are in the closed state. A voltage is applied to the thyristors of the inverters:. Ud / 2. Up to the same voltage, the capacitor 18 is charged, with the polarity indicated in FIG. 2. Suppose that at the initial moment of time, control pulses arrived at the thyristors 13 and 14 of the inverter from the master oscillator. These thyristors open and on the transformer 6 a rectangular square wave begins to form. After time j, which is determined by the line-17 delay, the capacitor 8 through the open thyristor 14 and the primary winding 19 of the transformer 20 will begin to discharge. In this case, a voltage pulse, the polarity of which is indicated, will be induced in the secondary windings 21-24 of the transformer 20. In this case, the thyristors 31 and 32 of the inverter 2 will open and a half-wave of rectangular voltage will form on the transformer 7, the front of this voltage will be shifted relative to the voltage front on the transformer 6 for the time of the delay of the backward line 17. Similarly, the shift and formation of control pulses to subsequent inverters occurs. When applying control pulses from master oscillator 1.1 to thyristors I2 and 15 of inverter 1, thyristor | j 13 and 14 are closed, a second half-wave of rectangular voltage is formed on transformer 6. In this case, due to the fact that there will be a positive voltage drop on the printer 14, which is approximately U / through the time determined by the delay line 17, the capacitor 18 will be charged, and a control pulse will be generated on the secondary windings of the transformer 20 the thyristors 29 and 30 of the inverter 2. On the transformer 7 of the inverter 2, a second half-wave of the rectangular voltage will be formed, shifted relative to the voltage of the inverter 1 by the delay time of the delay line 17. Similar processes occur in subsequent inverters. The duration of the control pulses depends on the capacitance of the capacitor 18 and the size of the resistors 25-28. Thus, the converter generates a step alternating voltage on the load. By selecting the parameters of the delay line 17, one can learn any required phase shift of one inverter relative to another. Obtaining small phase shifts is not associated with a complication of the control system. If the delay lines are made controllable, it is possible to adjust the output value of the output voltage of the converter. In the simplest case, a saturation throttle can be used as a delay line, in which the delay time is controlled by the selection of the number of turns. If a self-oscillating inverter is used as an inverter 1, in this case there is no need for a master oscillator and an additional source for its power supply. The proposed converter is designed and manufactured. Claim 1. A constant-to-variable-to-variable step converter containing centrist thyristor inverters loaded onto transformers, the output windings of which are connected in series and form the common output of the converter, and the master oscillator controlling the operation of the first inverter, characterized in that it is shared simplify and increase reliability, parallel to one of the thyristors of each K-th inverter is connected a chain consisting of a series-connected capacitor, a delay line and a primary circuit Offsets of the pulse transformer, the secondary windings of which, through resistors, are connected to the control junctions of the corresponding thyristors K + l of the inverter. 2. The converter according to Claim 1, characterized in that, in order to regulate an output voltage of as little as 1, the delays are made controllable. 3, the Converter according to claim. Ij of the fact that the delay lines are dense in the form of droplets of saturation. Sources of information taken into account in the examination of K. Konstantinov L.G. Multiphase transducers on transistors M., Energie, 1972. 2. Rudenko B.C., Senko V.I., Chizhenko I.M. Converting technique. Klev, Vishcha school, 1978, p. 399-409. 3. Modern tasks of conversion technology. - Abstracts reporting, Part 4, Kiev, Institute of Electrodynamics, Academy of Sciences of the Ukrainian GCP, 1975, p. 126-135. f i9 Vf2 I. .TYVX rvyx 03. II 2 С I гЦ - I I УМ I 25 jrS. Ir-i i. and atJI